Method, apparatus and article for off-line certification in mobile applications

ABSTRACT

A tamper-resistant certification device receives a certified digital time stamp from a trusted third party, resets a time function and produces a time stamp receipt in an on-line mode; The tamper-resistant certification device receives a digital file from a mobile computing device, and produces a certified digitally signed digital file including a copy of the digital file, time stamp receipt and temporal offset in an off-line mode to evidence the content of the digital file within a defined tolerance of a day and/or time. A processor may be portioned into tamper and non-tamper resistant portions.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This disclosure generally relates to mobile computing applications, andparticularly to certification and/or authentication in mobile computingenvironments.

2. Description of the Related Art

There currently exist a large variety of mobile computing applicationsin which certification or authentication to provide proof of serviceswould be desirable. For example, many package delivery services orcouriers employ mobile computing devices (e.g., laptop and/or handheldcomputing devices) for tracking packages and parcels through delivery.These mobile computing devices are capable of downloading package orparcel location information from time-to-time, that permits the on-linetracking of a package or parcel through the entire delivery process. Themobile computing devices may also provide business process assurancessuch as “proof-of-delivery” (POD). For example, mobile computing devicesmay allow for electronic signature capture which may be offered as proofof delivery.

Current techniques for implementing proof-of-services rendered are farfrom being non-repudiable. For example, electronic bitmaps of signaturescan be easily applied to receipts other than the receipt for which theyare intended. Further, mobile computing systems can easily be tamperedwith to forge electronic receipts, electronic signatures, and evenbiometric data. Security is a growing concern for the delivery ofdocuments and/or packages. Non-repudiable transaction certification isnecessary as true proof-of-service or -delivery. Without suchcertification, service providers will have to resort to time-consumingmanual business practices to establish proof of service. Such manualpractices increase labor costs and increase the billing cycle time.

Cryptographic techniques can be employed advantageously in non-mobilecomputing environments. For example, some cryptographic techniques maybe used to achieve confidentiality (i.e., keep information from all butthose authorized to have access). Also, some cryptographic techniquescan offer data integrity (i.e., allowing one to detect unauthorizedalteration or manipulation of data such as insertion, deletion orsubstitution). Additionally, some cryptographic techniques may providefor authentication (i.e., allowing one to verify the origin, date oforigin, data content, and time sent of both data and the sender).Further, some cryptographic techniques may be employed fornon-repudiation (i.e., prevent an entity from denying previouscommitments or actions). Non-repudiation typically involves a trustedthird party. One cryptographic primitive is the digital signature, whichis fundamental in authentication, authorization and non-repudiation. Adigital signature is a means for an entity to bind its identity with apiece of information. The signing process entails transforming themessage and some secret information held by the entity into a tag calleda signature.

Techniques and devices to provide for non-repudiation proof-of-serviceand/or proof-of-delivery in mobile computing environments are highlydesirable, particularly for package delivery and courier applications.

BRIEF SUMMARY OF THE INVENTION

In one aspect, a method of producing certifications of digital filescomprises from time-to-time in an on-line mode, receiving a certifiedtime stamp at a tamper-resistant certification device from a remotesource remotely located with respect to the tamper-resistantcertification device; in response to receiving the certified time stamp,providing a time stamp receipt to the remote source from thetamper-resistant certification device; from time-to-time, in an off-linemode, receiving a digital file for certification from a local sourcelocally located with respect to the tamper-resistant certificationdevice; determining a temporal offset from a last receipt of one of thecertified time stamps received at the tamper-resistant certificationdevice; and producing a certified digital file comprising the contentsof the digital file, the time stamp receipt, and an indication of thedetermined temporal offset from the last receipt of one of the certifiedtime stamps.

In another aspect, a method of producing certifications of digital filescomprises from time-to-time, establishing remote communications with aremotely located trusted third party; in response to the receipt of thecertified time stamp, resetting a timer function; providing a time stampreceipt to the trusted third party upon at least one of receiving thecertified time stamp and a successful resetting of the timer function;and terminating the remote communications with the trusted third party.

In yet another aspect, a tamper-resistant certification device toproduce certification of digital files comprises a tamper-resistanthousing, having an interior and an exterior; at least one communicationsport accessible from the exterior of the housing; a processor receivedin the housing and coupled to the at least one communications port, theprocessor configured to: from time-to-time in an on-line mode, receive acertified time stamp at a tamper-resistant certification device from aremote source remotely located with respect to the tamper-resistantcertification device; in response to receipt of the certified timestamp, provide a time stamp receipt to the remote source from thetamper-resistant certification device; and from time-to-time, in anoff-line mode, receive a digital file for certification from a localsource locally located with respect to the tamper-resistantcertification device; determine a temporal offset from a last receipt ofone of the certified time stamps received at the tamper-resistantcertification device; and produce a certified digital file comprisingthe contents of the digital file, the time stamp receipt, and anindication of the determined temporal offset from the last receipt ofone of the certified time stamps.

In still another aspect, a processor readable medium stores instructionsfor causing a processor in tamper-resistant certification device toproduce certification of digital files by: from time-to-time in anon-line mode, receiving a certified time stamp at a tamper-resistantcertification device from a remote source remotely located with respectto the tamper-resistant certification device; in response to receivingthe certified time stamp, providing a time stamp receipt to the remotesource from the tamper-resistant certification device; and fromtime-to-time, in an off-line mode, receiving a digital file forcertification from a local source locally located with respect to thetamper-resistant certification device; determining a temporal offsetfrom a last receipt of one of the certified time stamps received at thetamper-resistant certification device; and producing a certified digitalfile comprising the contents of the digital file, the time stampreceipt, and an indication of the determined temporal offset from thelast receipt of one of the certified time stamps.

In a further aspect, a method of producing certifications of digitalfiles comprises from time-to-time, providing a certified time stamp to atamper-resistant certification device; and receiving a time stampreceipt from the tamper-resistant certification device; receiving arequest for verification and a certified digital file digitally signedwith a digital signature; verifying whether the digital signatureauthenticates the tamper-resistant device as a source of the certifieddigital file; determining whether a copy of the time stamp receiptreceived as a part of the certified digital file corresponds to thereceived time stamp receipt; and notifying a requester of an outcome ofthe determination.

In yet a further aspect, a tamper-resistant certification device toproduce certification of digital files comprises a tamper-resistanthousing, having an interior and an exterior; at least one communicationsport accessible from the exterior of the housing; a processor receivedin the housing and coupled to the at least one communications port, theprocessor configured to: from time-to-time, provide a certified timestamp to a tamper-resistant certification device; receive a time stampreceipt from the tamper-resistant certification device; receive arequest for verification and a certified digital file digitally signedwith a digital signature; verify whether the digital signatureauthenticates the tamper-resistant device as a source of the certifieddigital file; determine whether a copy of the time stamp receiptreceived as a part of the certified digital file corresponds to thereceived time stamp receipt; and notify a requester of an outcome of thedetermination.

In still a further aspect, a processor readable medium storesinstructions for causing a processor in a tamper-resistant certificationdevice to produce certification of digital files by: from time-to-time,providing a certified time stamp to a tamper-resistant certificationdevice; receiving a time stamp receipt from the tamper-resistantcertification device; receiving a request for verification and acertified digital file digitally signed with a digital signature;verifying whether the digital signature authenticates thetamper-resistant device as a source of the certified digital file;determining whether a copy of the time stamp receipt received as a partof the certified digital file corresponds to the received time stampreceipt; and notifying a requester of an outcome of the determination.

In still even a further aspect, a method of producing certifications ofdigital files comprises: from time-to-time in an on-line mode, receivinga certified time stamp at a tamper-resistant certification portion of aprocessor from a remote source remotely located with respect to thetamper-resistant certification device; in response to receiving thecertified time stamp, providing a time stamp receipt to the remotesource from the tamper-resistant certification portion of the processor;and from time-to-time, in an off-line mode, receiving a digital file forcertification via a non-tamper resistant portion of the processor;determining a temporal offset from a last receipt of one of thecertified time stamps received at the tamper-resistant portion of theprocessor; and producing a certified digital file comprising thecontents of the digital file, the time stamp receipt, and an indicationof the determined temporal offset from the last receipt of one of thecertified time stamps.

In yet still even a further aspect, a tamper-resistant certificationdevice to produce certification of digital files comprises: a housing,having an interior and an exterior; at least one communications portaccessible from the exterior of the housing; a processor received in thehousing, the processor partitioned into a tamper-resistant portion and anon-tamper resistant portion, the processor coupled to the at least onecommunications port, and configured to: from time-to-time in an on-linemode, receive a certified time stamp at a tamper-resistant portion ofthe processor from a remote source remotely located with respect to thetamper-resistant certification device; in response to receipt of thecertified time stamp, provide a time stamp receipt to the remote sourcefrom the tamper-resistant certification device; and from time-to-time,in an off-line mode, receive a digital file for certification at thetamper-resistant portion of the processor; determine a temporal offsetfrom a last receipt of one of the certified time stamps received at thetamper-resistant portion of the processor; and produce a certifieddigital file comprising the contents of the digital file, the time stampreceipt, and an indication of the determined temporal offset from thelast receipt of one of the certified time stamps.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING(S)

In the drawings, identical reference numbers identify similar elementsor acts. The sizes and relative positions of elements in the drawingsare not necessarily drawn to scale. For example, the shapes of variouselements and angles are not drawn to scale, and some of these elementsare arbitrarily enlarged and positioned to improve drawing legibility.Further, the particular shapes of the elements as drawn, are notintended to convey any information regarding the actual shape of theparticular elements, and have been solely selected for ease ofrecognition in the drawings.

FIG. 1 is a schematic view of a computing environment according to oneillustrated embodiment, comprising a tamper-resistant certificationdevice, mobile computing system, trusted third party computing system,and a wide area communications network, such as the Internet.

FIG. 2 is a schematic diagram showing communications between thetamper-resistant certification device and the trusted third partycomputing system in an on-line mode.

FIG. 3A is a schematic diagram showing communications between thetamper-resistant certification device and the mobile computing systemduring an off-line mode, according to one illustrated embodiment.

FIG. 3B is a schematic diagram showing communications between atamper-resistant certification portion and a non-tamper-resistantportion of a logically partitioned microprocessor in the mobilecomputing system during an off-line mode, according to one illustratedembodiment.

FIG. 4 is a functional block diagram showing the tamper-resistantcertification device and mobile computing system according to oneillustrated embodiment.

FIG. 5 is a schematic diagram structure of a certified timestamp receiptdata structure returned by the tamper-resistant certification device tothe trusted third party computing system according to one illustratedembodiment.

FIG. 6 is a schematic diagram of a certified digital file data structurereturned by the certification device to the mobile computing systemaccording to one illustrated embodiment.

FIG. 7 is a flow diagram of a method of certifying files according toone illustrated embodiment.

DETAILED DESCRIPTION OF THE INVENTION

In the following description, certain specific details are set forth inorder to provide a thorough understanding of various embodiments of theinvention. However, one skilled in the art will understand that theinvention may be practiced without these details. In other instances,well-known structures and methods associated with computing systems,networks, data structures, various cryptographic techniques and otherdata security structures and techniques have not been shown or describedin detail to avoid unnecessarily obscuring descriptions of theembodiments of the invention.

Unless the context requires otherwise, throughout the specification andclaims which follow, the word “comprise” and variations thereof, suchas, “comprises” and “comprising” are to be construed in an open,inclusive sense, that is as “including, but not limited to.”

Reference throughout this specification to “one embodiment” or “anembodiment” means that a particular feature, structure or characteristicdescribed in connection with the embodiment is included in at least oneembodiment of the present invention. Thus, the appearances of thephrases “in one embodiment” or “in an embodiment” in various placesthroughout this specification are not necessarily all referring to thesame embodiment. Furthermore, the particular features, structures, orcharacteristics may be combined in any suitable manner in one or moreembodiments.

The headings provided herein are for convenience only and do notinterpret the scope or meaning of the claimed invention.

FIG. 1 shows a tamper-resistant certification device 10 that may beselectively communicatively coupled to a trusted third party computingsystem 12, for example, via a wide area network (WAN) such as theInternet 14 during an on-line mode, as illustrated by broken line 16 andsolid line 18. The tamper-resistant certification device 10 may also beselectively coupled to a mobile computing device 20 during an off-linemode, for example, via a local area network (LAN) and/or non-networkcommunications link such as a serial or parallel cable, or infraredtransceiver as illustrated by broken line 22. As will be evident tothose of skill in the art from this disclosure, the tamper-resistantcertification device 10 may provide a substantial improvement to thenon-repudiation of proof-of-service and/or proof-of-delivery in mobilecomputing environments, by ensuring that certification is provided by adevice that is not subject to tampering by the end-user or otherindividuals.

The trusted third party computing system 12 can take any of a variety offorms, such as a micro- or personal computer, a mini-computer, aworkstation, or server computing system. In practice, the trusted thirdparty computing system 12 will typically take the form of a networkserver, such as a web server, the details of which are commonlyunderstood by those skilled in the art. For example, the trusted thirdparty computing system 12 may take the form of a network serverexecuting an operating system such as Windows NT 4.0 Server, and/orWindows 2000 Server, available from Microsoft Corporation of Redmond,Wash.

The trusted third party computing system 12 is preferably operated by atrusted third party, that is a party without a stake in the outcome of acontest between a first and second party, for example, a first partydelivering a package and a second party receiving the package. Thetrusted third party serves as a neutral judge should some resolution berequired. The neutrality of the trusted third party allows both thefirst and second parties to trust any decisions made by the third party.

Trusted third parties are currently known to act as certificationauthorities, i.e., responsible for establishing and vouching forauthenticity of public keys, name servers responsible for managing aname space of unique user names, registration authorities responsiblefor authorizing entities distinguishing by unique names as members of asecurity domain, key generator (i.e., creating public, private key pairsand symmetric keys or passwords), and acting as certificate directory(i.e., a certificate database or server accessible for read-access byusers). Trusted third parties are also known to serve as key servers orauthentication servers, facilitating key establishment between otherparties and as key management facilitators (i.e., providing a number ofservices including storage and archival of keys, audit collection andreporting tools). Trusted third parties are also known to act astime-stamp agents, used to assert the existence of a specified documentat a certain point in time or affix a trusted date to a transaction ordigital message, act as notary agents (i.e., used to verify digitalsignatures at a given point in time to support non-repudiation or moregenerally establish the truth of any statement at a given point intime), and act as key escrow agents (i.e., used to provide third partyaccess to user's secret keys under special circumstances).

The mobile computing system 20 may take any of a variety of forms, suchas a micro- or personal computer, mini-computer, or workstation, butwill typically take the form of a lap-top computing system or a palm-topor hand-held computing appliance. The mobile computing system mayinclude a number of communications ports and/or cards, for establishingwired or wireless communications with external devices and/or networks.For example, such communications may occur over serial or parallel wiredchannels. For example, such communications may occur over wirelesschannels such as radio frequency (RF) including microwavecommunications, and/or via light including infrared.

The wide area network 14 may take any form of network, however willtypically take the form of the Internet, or a proprietary intranet orextranet.

FIG. 2 illustrates exemplary the communications between thetamper-resistant certification device 10 and the trusted third partycomputing system 12 during an on-line mode, in which thetamper-resistant certification device 10 is communicatively coupled tothe trusted third party computing system 12, for example via the WAN orInternet 14. The trusted third party computing system 12 may optionallyprovide PKI keys 24 to the tamper-resistant certification device 10, orPKI keys may be generated by the tamper-resistant certification device10 or some other device. The trusted third party computing system 12 mayalso provide a certified timestamp 26 to the tamper-resistantcertification device 10. In response to receipt of the certified timestamp 26, the tamper-resistant certification device 10 may provide acertified timestamp receipt 28 to the trusted third party computingsystem 12, as described in greater detail below.

FIG. 3A illustrates exemplary communications between thetamper-resistant certification device 10 and the mobile computing system20 during an off-line mode, in which the tamper-resistant certificationdevice is not communicatively coupled to the trusted third partycomputing system 12. The mobile computing system 20 may provide adocument or digest to the tamper-resistant certification device forcertification in the form of a digital file 30. In response, thetamper-resistant certification device 10 may provide a digitally signedcertified digital file 32 to the mobile computing system 20, asdescribed in greater detail below.

FIG. 3B illustrates exemplary communications between logicallypartitioned portions of a processor such as a microprocessor 31 (e.g.,XScale processor) in the mobile computing system 20 during the off-linemode, in which the mobile computing system 20 is not communicativelycoupled to the trusted third party computing system 12. In particular,the microprocessor 31 is partitioned (e.g., logically partitioned) intoa tamper-resistant portion 35 and a non-tamper resistant portion 37. Thetamper-resistant portion 35 may execute a predefined set ofinstructions, and is not effected by changes of clock speed or loss ofpower without at least indicating that such a change or loss hasoccurred, and may require a resetting of the certification function byreceipt of a new certified time stamp before creating any furtherdigitally signing certified digital files.

FIG. 4 is a schematic diagram of the tamper-resistant certificationdevice 10 according to one illustrated embodiment. The tamper-resistantcertification device 10 comprises a housing 33, a processor 34,nonvolatile memory 36, a timer function provided by a first delta timecounter 4Oa and optionally a second delta time counter 40 b, and aswitch 42 selectively actuatable by the processor 34 for resetting thefirst and second delta time counters 40 a, 40 b, respectively. Thehousing 33 encloses the processor 34, nonvolatile memory 36, first deltatime counter 40 a, a second delta time counter 40 b, and the switch 42,and protects such from tampering (i.e., tamper resistant, as discussedmore fully below).

The tamper-resistant certification device 10 may include one or morecommunications ports or cables 44 for transmitting and/or receivingdata. In some embodiments, the communications ports or cables 44 is theonly external interface for the tamper-resistant certification devices10, enhancing the tamper-resistant characteristics of thetamper-resistant certification device 10 by limiting the number ofpoints at which the internal components may be physically orelectronically accessed.

The tamper-resistant certification device 10 may optionally include apower port or cable 46 to couple to an external power source 48 whichmay or may not be provided from the mobile computing system 20. In suchan embodiments, the tamper-resistant certification device may employ thepower to recharge internal power source(s), enhancing thetamper-resistant characteristics of the tamper-resistant certificationdevice 10 by limiting the ability to manipulate the timer functionprovided by the delta time counters 40 a, 40 b.

The processor 34 executes instructions stored in ROM 38 based on datastored in the nonvolatile memory 36 and/or ROM 38. At any given time thenonvolatile memory 36 may store one or more of PKI keys 24, currentcertified timestamp 26, certified timestamp receipt 28, and a timestampreceipt counter 50. The timestamp receipt counter 50 is incremented eachtime a certified timestamp 26 is received by the tamper-resistantcertification device 10 to maintain track of the number of certifiedtimestamps received. In particular, the processor 34 may increment thetimestamp receipt counter 50 each time the delta time counters 40 a, 40b are reset based on a signal sent over the counter reset line 58.

The delta time counters 40 a, 40 b each include a respective crystalclock 54 a, 54 b, respectively and a respective embedded rechargeablebattery with an analog-to-digital (A/D) level reader 56 a, 56 b. Thebatteries 56 a, 56 b preferably have different storage capacities toprevent both batteries 56 a, 56 b from running out of charge at the sametime. The processor 34 can provide a signal over reset line 58 to resetthe crystal clocks 54 a, 54 b in response to receipt of a certifiedtimestamp 26. The processor 34 receives an indication of the batterycharge states via line 124. The processor 34 selects battery charge online 62 which controls switch 42. Battery charge is supplied via eitherline 60 a, or line 60 b.

As used herein and in the claims, the term “tamper-resistant” includesdevices which cannot be easily modified by tampering. Such devices mayinclude housings 33 that protect the contents housed therein fromphysical access (e.g., housing that are impossible or difficult to open,or that provide an indication, visual or otherwise, that the interior ofthe housing has been physically accessed). This level of securityprevents physical tampering, for example, physical tampering of thedelta time counters 40 a, 40 b. In another aspect, tamper resistantdevices may also include devices which prevent the replacement of powersupplies, such as batteries, or which indicate when a power supply hasbeen replaced. In a further aspect, tamper resistant devices may includedevices that prevent unauthorized changes to the configuration orprogramming. Examples of such devices, may include those employingfirmware for storing instructions, and those which preclude changes tothe operation or execution of the microprocessor, for example, devicesemploying an application specific integrated circuit ASIC or otherspecial purpose computer or processor. This level of security preventselectronic tampering, for example, access to the contents of randomaccess memory (RAM) or read only memory (ROM).

FIG. 5 shows one illustrated embodiment of a data structure for thecertified time stamp receipt 28 in the form of a monolithic digital filestructure comprising a device identifier 64, copy of the certifiedtimestamp 26 and an indication 66 of the contents of the timestampreceipt counter 50 (FIG. 4). The monolithic file structure ensures thatcomponents of the certified time stamp receipt 28 may not be removed,changed, substituted or otherwise tampered, without rendering thecertified time stamp receipt 28 invalid.

FIG. 6 shows one illustrated embodiment of a data structure for thedigitally signed certified digital file in the form of a monolithicsigned digital file structure comprising the device identifier 64, acopy 68 of the original digital file 30 (FIGS. 3A and 3B), a copy 70 ofthe current certified timestamp 26, a copy 72 of the certified timestampreceipt 28 and an indication of one or more elapsed times 74. Themonolithic file structure ensures that components of the signed digitalfile 32 may not be removed, changed, substituted or otherwise tampered,without rendering the signed digital file 32 invalid.

FIG. 7 shows a method 100 according to one illustrated embodiment, wherethe tamper-resistant certification device 10 operates in an on-line modecommunicatively coupled to the third party computing system 12 and in anOff-line mode communicatively coupled to the mobile computing system 20.

At 102, communication is established between the tamper-resistantcertification device 10 and the trusted third party 12. Optionally at104, the tamper-resistant certification device 10 receives public keyinfrastructure (PKI) keys, for example, from the trusted third partycomputing system 12. At 106, the trusted third party computing system 12generates a certified timestamp 26 (FIG. 2). At 108, thetamper-resistant certification device 10 receives the certifiedtimestamp 26 from the trusted third party computing system 12. At 110,the processor 34 (FIG. 4) of the tamper-resistant certification device10 resets the timer functions 40 a, 40 b. At 112, the tamper-resistantcertification device 10 provides a certified timestamp receipt 28 (FIGS.2 and 5) to the trusted third party computing system 12. At 114, thetrusted third party computing system 12 receives the certified timestampreceipt 28. At 116, communications are terminated between thetamper-resistant certification device 10 and the trusted third partycomputing system 12.

At 118, communications are established between the tamper-resistantcertification device 10 and the mobile computing system 20. At 120, thetamper-resistant certification device 10 receives a document ordigestive document in the form of a digital file 30 (FIGS. 3A and 3B)from the mobile computing device 20. At 122, the tamper-resistantcertification device 10 produces the digitally signed certified digitalfile 32 (FIGS. 3A and 3B), that includes the embedded timestamp 26,timestamp receipt 28, copy of contents of the digital file 30, andindication of the elapsed time 74 (FIG. 6).

The digitally signed certified digital file 32 constitutesnon-repudiable evidence of the contents of the digital file 30 at agiven date and time, within a defined tolerance defined by the elapsedor delta time, and which may be verified by the trusted third party.

Although specific embodiments of and examples for the certificationsystem, tamper-resistant certification device and method ofcertification are described herein for illustrative purposes, variousequivalent modifications can be made without departing from the spiritand scope of the invention, as will be recognized by those skilled inthe relevant art. The teachings provided herein of the invention can beapplied to document originating sources other than the mobile computingsystem generally described above, and may employ certificationauthorities other than the trusted third party computing systemgenerally described above.

The various embodiments described above can be combined to providefurther embodiments. All of the U.S. patents, U.S. patent applicationpublications, U.S. patent applications, foreign patents, foreign patentapplications and non-patent publications referred to in thisspecification and/or listed in the Application Data Sheet, including butnot limited to The Handbook of Applied Cryptography, Menezes, vanOorschot and Vanstone, CRC Publishing, are incorporated herein byreference, in their entirety. Aspects of the invention can be modified,if necessary, to employ systems, circuits and concepts of the variouspatents, applications and publications to provide yet furtherembodiments of the invention.

These and other changes can be made to the invention in light of theabove-detailed description. In general, in the following claims, theterms used should not be construed to limit the invention to thespecific embodiments disclosed in the specification and the claims, butshould be construed to include all certification systems and methodsthat operated in accordance with the claims. Accordingly, the inventionis not limited by the disclosure, but instead its scope is to bedetermined entirely by the following claims.

1. A method of producing certifications of digital files, the methodcomprising: from time-to-time, while a tamper-resistant certificationdevice is in an on-line mode, receiving a certified time stamp at thetamper-resistant certification device from a remote source remotelylocated with respect to the tamper-resistant certification device,wherein the tamper-resistant certification receives at a time of receipta last certified time stamp; in response to receiving the certified timestamp, providing a time stamp receipt to the remote source from thetamper-resistant certification device; and from time-to-time, while thetamper-resistant certification device is in an off-line mode, receivinga digital file for certification at the tamper-resistant certificationdevice, the digital file from a local source locally located withrespect to the tamper-resistant certification device; determining atemporal offset from the time of receipt of the last certified timestamp received at the tamper-resistant certification device; andproducing a certified digital file at the tamper-resistant certificationdevice, the certified digital file comprising the contents of thedigital file, the stamp receipt, and an indication of the determinedtemporal offset from the time of receipt of the last certified timestamp.
 2. The method of claim 1 wherein receiving a certified time stampat a tamper-resistant certification device from a remote source remotelylocated with respect to the tamper-resistant certification devicecomprises receiving a certified time stamp communications comprising adigital signature from a trusted third party over a networkcommunications link, where the digital signature authenticates thetrusted third party as the source of the certified time stamp.
 3. Themethod of claim 1 wherein providing a time stamp receipt, to the remotesource from the tamper-resistant certification device comprisestransmitting a time stamp receipt communication to a trusted third partyover a network communications link where the time stamp receiptcommunication comprises a digital signature and the digital signatureauthenticating the tamper-resistant certification device as a solesource of the time stamp receipt.
 4. The method of claim 1, furthercomprising: incrementing a time stamp receipt counter in thetamper-resistant certification device upon receiving the certified timestamp at the tamper-resistant certification device; and providing acontents of the time stamp receipt counter in the time stamp receiptprovided to the remote source from the tamper-resistant device.
 5. Themethod of claim 1, further comprising: resetting a timer function inresponse to receiving of the certified time stamp at thetamper-resistant certification device.
 6. The method of claim 5 whereinresetting a timer function in response to receiving of the certifiedtime stamp at the tamper-resistant certification device comprisesresetting a first clock in the tamper-resistant certification device andresetting a second clock in the tamper-resistant certification device,the second clock different from the first clock.
 7. The method of claim1 wherein determining a temporal offset from the time of receipt of thelast certified time stamp comprises: a. determining an elapsed time of afirst clock of the tamper-resistant certification device, afterresetting the first clock of the tamper-resistant certification devicein response to receipt of the last certified time stamp by thetamper-resistant certification device.
 8. The method of claim 1 whereinproducing a certified digital file includes producing a monolithicdigital file structure comprising the contents of the digital file, thetime stamp receipt, an indication of the determined temporal offset fromthe last receipt of one of the certified time stamps, and furthercomprising a device identifier uniquely identifying the tamper-resistantcertification device, and a copy of the certified time stamp.
 9. Themethod of claim 1, further comprising: establishing temporarycommunications with the remotely located source via a wide area networkin the online mode to receive the certified time stamp and to providethe time stamp receipt; establishing communications with the localsource via at least one of a local area network or a non-networkcommunications link in an offline mode to receive the digital file andto produce the certified digital file, and providing the certifieddigital file to the local source via the at least one of the local areanetwork or the non-network communications link.
 10. A method ofproducing certifications of digital files, the method comprising: b.From time to time, i. establishing remote communications with a remotelylocated trusted third party over a communications path extending betweenthe trusted third party and a certification device; ii. receiving acertified time stamp from the trusted third party at the certificationdevice; iii. verifying that the certified time stamp was created by thetrusted third party as a precondition to resetting the timer function atthe certification device; iv. in response to the verification of thecertified time stamp, resetting the timer function at the certificationdevice; v. providing to the trusted third party a time stamp receiptfrom the certification device upon at least one of receiving thecertified time stamp receipt or a successful resetting of the timerfunction; vi. terminating the remote communications with the trustedthird party over the communication path extending between the trustedthird party and the certification device.
 11. The method of claim 10,further comprising: incrementing a time stamp receipt counter uponreceiving the certified time stamp; and providing a contents of the timestamp receipt counter in the time stamp receipt.
 12. The method of claim10, further comprising: from time-to-time, establishing localcommunications with a locally located mobile computing system; receivinga digital file for certification from the locally located mobilecomputing system at the certification device; determining a temporaloffset from at least one of: a last receipt of the certified time stamp,a last successful resetting of the timer function, or a last providingof the time stamp receipt; and producing a certified digital file at thecertification device, the certified digital file comprising: thecontents of the received digital file, a most recently received one ofthe certified time stamps, a most recently provided one of the certifiedtime stamp receipts, and an indication of the determined temporaloffset.
 13. The method of claim 12 wherein resetting a timer functioncomprises resetting a first clock powered by a first power source andresetting a second clock powered by a second power source where thesecond clock is different from the first clock and the second powersource is different from the first power source, and wherein producing acertified digital file comprising an indication of the determinedtemporal offset comprises producing a digital file comprising a firstdetermined offset from the first clock and a second determined offsetfrom the second clock.
 14. The method of claim 13, further comprising:supplying power to the first clock from the first power source; andsupplying power to the second clock from the second power source, wherethe second power source has a greater charge capacity than the firstpower source.
 15. The method of claim 12 wherein establishing localcommunications with a locally located mobile computing system occursafter terminating the remote communications with the trusted thirdparty.
 16. The method of claim 12 wherein producing a certified digitalfile comprises digitally signing the certified digital file with adigital signature, the digital signature authenticating thecertification device as the sole source of the certified digital file,and further comprising: providing the digitally signed certified digitalfile to the locally located mobile computing system.
 17. The method ofclaim 16, further comprising: receiving at least one set of biometricdata captured from an individual who is a party to a transaction towhich the digital file pertains, and wherein producing a certifieddigital file comprises incorporating the biometric data in the digitallysigned certified digital file.
 18. A method of producing certificationsof digital files, the method comprising; from time-to-time, establishingremote communications with a remotely located trusted third party;receiving a certified time stamp from the trusted third party; inresponse to the receipt of the certified time stamp, resetting a timerfunction; providing a time stamp receipt to the trusted third party uponat least one of receiving the certified time stamp receipt or asuccessful resetting of the timer function; terminating the remotecommunications with the trusted third party; and temporarily disablingthe producing of the certified digital files following a discharge of abattery below a defined threshold, until the timer function is reset inresponse to receipt of one of the certified time stamps.
 19. Atamper-resistant certification device to produce certification ofdigital files, the tamper-resistant certification device comprising: atamper-resistant housing, having an interior and an exterior; at leastone communications port accessible from the exterior of the housing; aprocessor received in the housing and coupled to the at least onecommunications port, the processor configured to: from time-to-time inan on-line mode, receive a certified time stamp at a tamper-resistantcertification device from a remote source remotely located with respectto the tamper-resistant certification device; in response to receipt ofthe certified time stamp, provide a time stamp receipt to the remotesource from the tamper-resistant certification device; and fromtime-to-time, in an off-line mode, receive a digital file forcertification from a local source locally located with respect to thetamper-resistant certification device; determine a temporal offset froma last receipt of one of the certified time stamps received at thetamper-resistant certification device; and produce a certified digitalfile comprising the contents of the digital file, the time stampreceipt, and an indication of the determined temporal offset from thelast receipt of one of the certified time stamps.
 20. Thetamper-resistant certification device of claim 19 wherein the processoris further configured to: increment a time stamp receipt counter in thetamper-resistant certification device upon receiving the certified timestamp at the tamper-resistant certification device; reset a timerfunction in response to receiving of the certified time stamp at thetamper-resistant certification device; and provide a contents of thetime stamp receipt counter in the time stamp receipt provided to theremote source from the tamper-resistant device.
 21. A processor readablemedium storing instructions for causing a processor in atamper-resistant certification device to produce certification ofdigital files, by: from time-to-time in an on-line mode, receiving acertified time stamp at a tamper-resistant certification device from aremote source remotely located with respect to the tamper-resistantcertification device; in response to receiving the certified time stamp,providing a time stamp receipt to the remote source from thetamper-resistant certification device; and from time-to-time, in anoff-line mode, receiving a digital file for certification from a localsource locally located with respect to the tamper-resistantcertification device; determining a temporal offset from a last receiptof one of the certified time stamps received at the tamper-resistantcertification device; and producing a certified digital file comprisingthe contents of the digital file, the time stamp receipt, and anindication of the determined temporal offset from the last receipt ofone of the certified time stamps.